Regulation of the carotid body type-1 cell by lipid signalling pathways

Abstract

Despite several proposed theories, the precise mechanism underlying acute oxygen sensing in type-1 cells of the carotid body remains elusive. This thesis investigates the role of Gq- coupled receptors and PLC signalling molecules in the regulation of carotid body type-1 cells by utilizing Ca2+ measurements and single channel electrophysiology. This thesis investigates the involvement of these signalling molecules in hypoxia-induced [Ca2+]i rise and TASK channel inhibition in type-1 cells. In addition, this thesis examines the role of PLC signalling molecules in mediating the effects of metabolic poisons and volatile anaesthetics on TASK channels in type-1 cells. This thesis seeks to address the question as to whether there might be a common signalling pathway mediating all these effects. Specifically, it proposes that lipid signalling may ultimately be central to all these forms of TASK channel regulation. Following the general introduction and methods chapters, chapter 3 examines the effects of Gq- coupled receptors and PLC signalling molecules on the hypoxia-induced [Ca2+]i rise in type-1 cell. The results show that hypoxia-induced [Ca2+]i rise was sensitive to alterations in Gq-coupled receptors and PLC-signalling molecules, suggesting that these signalling molecules are involved in mediating the hypoxia-induced [Ca2+]i rise in type-1 cells. Chapter 4, further examines the role of these signalling molecules by looking at their effects on the activity of TASK channels in type-1 cells. This chapter presents novel findings demonstrating the involvement of PLC signalling molecules in mediating the hypoxic inhibition of TASK channels in type 1 cells. It proposes a model for acute oxygen sensing in these cells, incorporating findings from chapters 3 and 4. Chapter 5 examines the role of PLC signalling molecules in mediating the effects of metabolic inhibitors on TASK channels. Metabolic inhibitors are known to inhibit TASK channels in type-1 cells and other cell types. We further confirmed this and showed that these effects are not likely to be mediated by PLC-produced DAG. Chapter 6 examines the interactions between DAG and halothane on TASK channels in type-1 cells. We demonstrated that DiC8, a DAG analogue, induced a strong, reversible, and dose-dependent inhibition of TASK channels and inhibited the halothane-induced activation of these channels. These novel findings support the hypothesis that anaesthetics and endogenous ligands may compete for binding sites in sensitive proteins. In conclusion, this thesis presents novel findings on the role of Gq-coupled receptors and PLC signalling molecules in the regulation of carotid body type-1 cells and suggests that these signalling molecules are involved in mediating the responses of type-1 cells to various endogenous and exogenous stimuli. Additionally, it posits that PLC signalling molecules establish a connection between metabolic function and the modulation of TASK channels by hypoxia in type-1 cells.